Down-Regulated Gene Expression of GKN1 and GKN2 as Diagnostic Markers for Gastric Cancer
Gastric Cancer (GC) has high morbidity and fatality
rate in various countries. It is still one of the most frequent and
deadly diseases. Gastrokine1 (GKN1) and gastrokine2 (GKN2) genes
are highly expressed in the normal stomach epithelium and play
important roles in maintaining the integrity and homeostasis of
stomach mucosal epithelial cells. In this study, 47 paired samples that
were grouped according to the types of gastric cancer and the clinical
characteristics of the patients, including gender and average of age.
They were investigated with gene expression analysis and mutation
screening by monitoring RT-PCR, SSCP and nucleotide sequencing
techniques. Both GKN1 and GKN2 genes were observed significantly
reduced found by (Wilcoxon signed rank test; p<0.05). As a result of
gene screening, no mutation (no different genotype) was detected. It
is considered that gene mutations are not the cause of gastrokines
inactivation. In conclusion, the mRNA expression level of GKN1 and
GKN2 genes statistically was decreased regardless the gender, age, or
cancer type of patients. Reduced of gastrokine genes seem to occur at
the initial steps of gastric cancer development.
[1] F. Kamangar, G.M. Dores, and W.F. Anderson, “Patterns of cancer
incidence, mortality, and prevalence across five continents: defining
priorities to reduce cancer disparities in different geographic regions of
the world” Journal of Clinical Oncology, vol. 24(14), pp. 2137-2150,
2006.
[2] R. Siegel, D. Naishadham, and A. Jemal, “Cancer statistics”, 2012. CA
Cancer Journal Clinical, vol. 62(1), pp. 10-29, 2012.
[3] K.D. Crew, and A.I. Neugut, “Epidemiology of gastric cancer” World
Journal Gastroenterol, vol. 12(3), pp. 354-362, 2006.
[4] B.J. Dicken, D.L. Bigam, C. Cass, J.R. Mackey, A. Joy, and S.M.
Hamilton, “Gastric adenocarcinoma review and considerations for future
directions” Ann Surg, vol. 241(1), pp. 27-39, 2005.
[5] C. K. Oine, Gastric cancer, 2nd edition, Weliy, New york, 2007; ch. 4,
pp. 64-711.
[6] D.M. Roder, “The epidemiology of gastric cancer” Journal of
Gastroetestinal, vol. 51, pp. 5-11, 2002.
[7] J.J. Du, K.F. Dou, S.Y. Peng, W.Z. Wang, Z.H. Wang, H.S. Xiao, W.X.
Guan, Y.B. Liu, and Z.Q. GAO, “Down-regulated full-length novel gene
GDDR and its effect on gastric cancer” Clinical surgery, vol. 83(13), pp.
1166-1168, 2003.
[8] Y. Yoshikawa, H. Mukai, F. Hino, K. Asada, and I. Kato, “Isolation of
two novel genes, downregulated in gastric cancer” Japan Journal of
Cancer Reseach, vol. 91(5), pp. 459-463, 2000.
[9] K.A. Oien, F. Gregor, S. Butler, R.K. Ferrier, I. Downie, Bryce, S.
Burns, and W.N. Keith, “Gastrokine 1 is abundantly and specifically
expressed in superficial gastric epithelium, down-regulated in gastric
carcinoma, and shows high evolutionary conservation” Journal Pathol,
vol. 203(3), pp. 789-797, 2004.
[10] J.H. Yoon, H. Song, C .Zhang, M .Jin, Y.H. Kang, S.W. Nam, J.Y. Lee,
and W.S. Park. “Inactivation of the Gastrokine 1 gene in gastric
adenomas and carcinomas” Journal of Pathology, vol. 223(5), pp. 618-
625, 2011.
[11] I. Kouznetsova, W. Laubinger, H. Kalbacher, T. Kalinski, F. Meyer, A.
Roessner, and W. Hoffmann, “Biosynthesis of gastrokine-2 in the human
gastric mucosa: restricted spatial expression along the antral gland axis
and differential interaction with TFF1, TFF2 and mucins” Journal of
Cell Physiology and Biochemistry, vol. 20(6), pp. 899-908, 2007.
[12] Y. Z. Igci, A. Arslan, E. Akarsu, S. Erkilic, M. Igci, S. Oztuzcu, B.
Cengiz, B. Gogebakan, E. A. Cakmak, and A. T. Demiryurek,
“Differential Expression of a Set of Genes in Follicular and Classic
Variants of Papillary Thyroid Carcinoma‖” Endocr Pathol, vol. 2,(22),
pp. 86-96, 2011.
[13] G.R. Yan, S.H. Xu, Z.L. Tan, and X.F. Yin, “Proteomics
characterization of gastrokine 1-induced growth inhibition of gastric
cancer cells” Proteomics, vol. 11(18), pp. 3657-3664, 2011.
[14] W. Mao, J. Chen, T.L. Peng, X.F. Yin, L.Z. Chen, and M.H. Chen.
“Dow-nregulation of gastrokine-1 in gastric cancer tissues and
restoration of its expression induced gastric cancer cells to apoptosis”
Journal of Experimental Clinical Cancer Research, vol. 23 pp. 31-49,
2012.
[15] G. Chu, S. Qi, G. Yang, K. Dou, J. Du, and Z. Lu, “Gastrointestinal tract
specific gene GDDR inhibits the progression of gastric cancer in a TFF1
dependent manner” Molecular Cell Biochemistry, vol. 359, pp. 369 374,
2012.
[16] S.F. Moss, J.W. Lee, E. Sabo, A.K. Rubin, J. Rommel, B.R. Westley,
F.E. May, J. Gao, P.A. Meitner, R. Tavares, and M.B, Resnick.
“Decreased expression of gastrokine 1 and the trefoil factor interactin
protein TFIZ1/GKN2 in gastric cancer: influence of tumor histology and
relationship to prognosis” Clinical Cancer Res, vol. 14(13), pp. 4161-
4167,2008.
[17] T.R. Menheniott, B. Kurklu, A.S. Giraud, “Gastrokines: stomachspecific
proteins with putative homeostatic and tumor suppressor roles”
American Journal of Physiology Gastrointestinal Liver Physiol, vol.
304(2), pp.109-121, 2013.
[18] O. Kim, J.H. Yoon, W.S. Choi, H. Ashktorab, D.T. Smoot, S.W. Nam,
J.Y. Lee, and W.S. Park, “GKN2 Contributes to the Homeostasis of
Gastric Mucosa by Inhibiting GKN1 Activity” Journal of Cell Physiol,
vol. 229(6), pp. 762-771, 2014.
[19] J.H. Yoon, Y.J. Choi, W.S. Choi, H. Ashktorab, D.T. Smoot, S.W. Nam,
J.Y. Lee, and W.S. Park, “GKN1- miR-185-DNMT1 axis suppresses
gastric carcinogenesis through regulation of epigenetic alteration and
cell cycle” Clinical Cancer Res, vol. 19(17), pp. 4599-4610, 2013.
[1] F. Kamangar, G.M. Dores, and W.F. Anderson, “Patterns of cancer
incidence, mortality, and prevalence across five continents: defining
priorities to reduce cancer disparities in different geographic regions of
the world” Journal of Clinical Oncology, vol. 24(14), pp. 2137-2150,
2006.
[2] R. Siegel, D. Naishadham, and A. Jemal, “Cancer statistics”, 2012. CA
Cancer Journal Clinical, vol. 62(1), pp. 10-29, 2012.
[3] K.D. Crew, and A.I. Neugut, “Epidemiology of gastric cancer” World
Journal Gastroenterol, vol. 12(3), pp. 354-362, 2006.
[4] B.J. Dicken, D.L. Bigam, C. Cass, J.R. Mackey, A. Joy, and S.M.
Hamilton, “Gastric adenocarcinoma review and considerations for future
directions” Ann Surg, vol. 241(1), pp. 27-39, 2005.
[5] C. K. Oine, Gastric cancer, 2nd edition, Weliy, New york, 2007; ch. 4,
pp. 64-711.
[6] D.M. Roder, “The epidemiology of gastric cancer” Journal of
Gastroetestinal, vol. 51, pp. 5-11, 2002.
[7] J.J. Du, K.F. Dou, S.Y. Peng, W.Z. Wang, Z.H. Wang, H.S. Xiao, W.X.
Guan, Y.B. Liu, and Z.Q. GAO, “Down-regulated full-length novel gene
GDDR and its effect on gastric cancer” Clinical surgery, vol. 83(13), pp.
1166-1168, 2003.
[8] Y. Yoshikawa, H. Mukai, F. Hino, K. Asada, and I. Kato, “Isolation of
two novel genes, downregulated in gastric cancer” Japan Journal of
Cancer Reseach, vol. 91(5), pp. 459-463, 2000.
[9] K.A. Oien, F. Gregor, S. Butler, R.K. Ferrier, I. Downie, Bryce, S.
Burns, and W.N. Keith, “Gastrokine 1 is abundantly and specifically
expressed in superficial gastric epithelium, down-regulated in gastric
carcinoma, and shows high evolutionary conservation” Journal Pathol,
vol. 203(3), pp. 789-797, 2004.
[10] J.H. Yoon, H. Song, C .Zhang, M .Jin, Y.H. Kang, S.W. Nam, J.Y. Lee,
and W.S. Park. “Inactivation of the Gastrokine 1 gene in gastric
adenomas and carcinomas” Journal of Pathology, vol. 223(5), pp. 618-
625, 2011.
[11] I. Kouznetsova, W. Laubinger, H. Kalbacher, T. Kalinski, F. Meyer, A.
Roessner, and W. Hoffmann, “Biosynthesis of gastrokine-2 in the human
gastric mucosa: restricted spatial expression along the antral gland axis
and differential interaction with TFF1, TFF2 and mucins” Journal of
Cell Physiology and Biochemistry, vol. 20(6), pp. 899-908, 2007.
[12] Y. Z. Igci, A. Arslan, E. Akarsu, S. Erkilic, M. Igci, S. Oztuzcu, B.
Cengiz, B. Gogebakan, E. A. Cakmak, and A. T. Demiryurek,
“Differential Expression of a Set of Genes in Follicular and Classic
Variants of Papillary Thyroid Carcinoma‖” Endocr Pathol, vol. 2,(22),
pp. 86-96, 2011.
[13] G.R. Yan, S.H. Xu, Z.L. Tan, and X.F. Yin, “Proteomics
characterization of gastrokine 1-induced growth inhibition of gastric
cancer cells” Proteomics, vol. 11(18), pp. 3657-3664, 2011.
[14] W. Mao, J. Chen, T.L. Peng, X.F. Yin, L.Z. Chen, and M.H. Chen.
“Dow-nregulation of gastrokine-1 in gastric cancer tissues and
restoration of its expression induced gastric cancer cells to apoptosis”
Journal of Experimental Clinical Cancer Research, vol. 23 pp. 31-49,
2012.
[15] G. Chu, S. Qi, G. Yang, K. Dou, J. Du, and Z. Lu, “Gastrointestinal tract
specific gene GDDR inhibits the progression of gastric cancer in a TFF1
dependent manner” Molecular Cell Biochemistry, vol. 359, pp. 369 374,
2012.
[16] S.F. Moss, J.W. Lee, E. Sabo, A.K. Rubin, J. Rommel, B.R. Westley,
F.E. May, J. Gao, P.A. Meitner, R. Tavares, and M.B, Resnick.
“Decreased expression of gastrokine 1 and the trefoil factor interactin
protein TFIZ1/GKN2 in gastric cancer: influence of tumor histology and
relationship to prognosis” Clinical Cancer Res, vol. 14(13), pp. 4161-
4167,2008.
[17] T.R. Menheniott, B. Kurklu, A.S. Giraud, “Gastrokines: stomachspecific
proteins with putative homeostatic and tumor suppressor roles”
American Journal of Physiology Gastrointestinal Liver Physiol, vol.
304(2), pp.109-121, 2013.
[18] O. Kim, J.H. Yoon, W.S. Choi, H. Ashktorab, D.T. Smoot, S.W. Nam,
J.Y. Lee, and W.S. Park, “GKN2 Contributes to the Homeostasis of
Gastric Mucosa by Inhibiting GKN1 Activity” Journal of Cell Physiol,
vol. 229(6), pp. 762-771, 2014.
[19] J.H. Yoon, Y.J. Choi, W.S. Choi, H. Ashktorab, D.T. Smoot, S.W. Nam,
J.Y. Lee, and W.S. Park, “GKN1- miR-185-DNMT1 axis suppresses
gastric carcinogenesis through regulation of epigenetic alteration and
cell cycle” Clinical Cancer Res, vol. 19(17), pp. 4599-4610, 2013.
@article{"International Journal of Medical, Medicine and Health Sciences:71523", author = "Amer A. Hasan and Mehri Igci and Ersin Borazan and Rozhgar A. Khailany and Emine Bayraktar and Ahmet Arslan", title = "Down-Regulated Gene Expression of GKN1 and GKN2 as Diagnostic Markers for Gastric Cancer", abstract = "Gastric Cancer (GC) has high morbidity and fatality
rate in various countries. It is still one of the most frequent and
deadly diseases. Gastrokine1 (GKN1) and gastrokine2 (GKN2) genes
are highly expressed in the normal stomach epithelium and play
important roles in maintaining the integrity and homeostasis of
stomach mucosal epithelial cells. In this study, 47 paired samples that
were grouped according to the types of gastric cancer and the clinical
characteristics of the patients, including gender and average of age.
They were investigated with gene expression analysis and mutation
screening by monitoring RT-PCR, SSCP and nucleotide sequencing
techniques. Both GKN1 and GKN2 genes were observed significantly
reduced found by (Wilcoxon signed rank test; p", keywords = "Diagnostic biomarker, gastric cancer, nucleotide
sequencing, semi-quantitative RT-PCR.", volume = "9", number = "6", pages = "532-4", }
